Geographic Information Systems (GIS) and ITS

Outlines •  Introduction •  What is GIS? •  What can we do with GIS? •  How does GIS work? •  Geography database & types of data •  Features and functionalities of GIS •  Applications of GIS

We Live in Two Worlds

Self-Regulating Managed

Natural World Constructed World

. . . These Are Increasingly In Conflict

Context and Content

•  Patterns •  Linkages •  Trends

•  Watersheds •  Communities •  Neighborhoods •  Districts

Seeing the Whole Managing Places

Example

Example

What is GIS?

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Geographic Information System (GIS) is a computer-based system including software, hardware, people, and geographic information

A GIS can: create, edit, query, analyze, and display map information on the computer

Geographic Information System

•  Geographic – Most of the data collected is associated with some location in space.

•  Information – characteristics (data), can be used to provide

meaningful information about a given location •  System – running operation on the information and

associated to the geography – which requires hardware, networks, software, data, and operational procedures

Who uses GIS? •  International organizations

–  The World Bank, UNEP, FAO, WHO, etc. •  Private industry

–  Transport, Real Estate, etc. •  Government

–  Ministries of Environment, Housing, Agriculture, etc. –  Local Authorities, Cities, Municipalities, etc. –  Provincial Agencies for Planning, Parks, Transportation,

etc. •  Non-profit organizations/NGO’s •  Academic and Research Institutions

What can you do with a GIS?

•  The possibilities are unlimited… –  Resource management –  Land use planning – Water and Sanitation Mapping –  Electricity network mapping –  Transportation routing –  Environmental impact assessment

How does a GIS work? •  GIS data has a spatial/geographic

reference

–  Such as:

•  a latitude & longitude •  a national coordinate system •  an address •  a district •  a wetland identifier •  a road name

Geography and Databases •  A GIS stores information about the world as

a collection of thematic layers that can be linked together by geography

Polygon 3 Scrub 17 Very high Clay

GIS provides Data Integration

Vectors Topology

Networks

Terrain

Surveys

Images

CAD Drawings

Annotation

Addresses

27 Main St.

Attributes

ABC

107’

3D Objects

Dimensions •  Roads •  Land Parcels •  Population •  Utilities •  Land Mines •  Hospitals •  Refugee Camps •  Wells •  Sanitation

Two fundamental types of data

•  Vector –  A series of x,y coordinates –  For discrete data represented as points, lines, polygons

•  Raster –  Grid and cells –  For continuous data such as elevation, slope, surfaces

•  A Desktop GIS should be able to handle both types of data effectively!

Raster

Vector

Real World

Data Representation

Representing Spatial Elements

Raster

Stores images as rows and columns of numbers with a Digital Value/Number (DN) for each cell.

Units are usually represented as square grid cells that are uniform in size.

Data is classified as “continuous” (such as in an image), or “thematic” (where each cell denotes a feature type.

Numerous data formats (TIFF, GIF, ERDAS.img etc)

Vector

Allows user to specify specific spatial locations and assumes that geographic space is continuous, not broken up into discrete grid squares

We store features as sets of X,Y coordinate pairs.

Representing Spatial Elements

Entity Representations

Points - simplest element

Lines (arcs) - set of connected points

Polygons - set of connected lines

We typically represent objects in space as three distinct spatial elements:

We use these three spatial elements to represent real world features and attach locational information to them.

•  In the raster data model, the cell value (Digital Number) is the attribute. Examples: brightness, landcover code, SST, etc.

•  For vector data, attribute records are linked to point, line & polygon features. Can store multiple attributes per feature. Vector features are linked to attributes by a unique feature number.

Attributes

Raster vs. Vector

Raster Advantages

The most common data format

Easy to perform mathematical and overlay operations

Satellite information is easily incorporated

Better represents “continuous”- type data

Vector Advantages

Accurate positional information that is best for storing discrete thematic features (e.g., roads, shorelines, sea-bed features.

Compact data storage requirements

Can associate unlimited numbers of attributes with specific features

Other features of a GIS •  Produce good cartographic products

(translation = maps) •  Generate and maintain metadata •  Use and share geoprocessing models •  Managing data in a geodatabase using

data models for each sector

GIS FUNCTIONALITY

GIS Functions

•  Data Assembly

•  Data Storage

•  Spatial Data Analysis and Manipulation

•  Spatial Data Output

GIS Functions Data Assembly

Maps RSI

Intel Database

Data Transfer

Direct Entry

Data Transfer

Keyboard

GPS

Data Input/Creation

Spatial data (ARC functions)

Attribute data (INFO or TABLES functions)

1 (Universe polygon)

2 3

4 5

GIS Storage

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GIS Functions

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GIS Functions

•  Common Manipulation –  Reclassification –  Map Projection changes

•  Common Analysis –  Buffering –  Overlay –  Network

Spatial Data Manipulation and Analysis

Spatial Analysis

•  Overlay function creates new “layers” to solve spatial problems

GIS Functions

•  Tables

•  Maps

•  Interactive Displays

•  3-D Perspective View

Spatial Data Output

The World Geographic Knowledge

Citizens

Inventory

Decision Support

APPLICATIONS

GIS Applications

•  Site selection –  Helicopter Landing Zones –  Amphibious Assault (Water Depth) –  Buffer Zones –  Flight Planning –  Battlefield Visualisation

Helicopter Landing Zones

HLZ sites

Amphibious Assault Planning

Spatial Analysis Proximity Analysis (Buffers)

1000 Meter Buffer of Railroads

Flight Planning

Flight Planning/Flythroughs

Battlefield Visualization and/or Situation Awareness

Other GIS Applications

•  Cross country movement –  Route planning –  Intervisibility study

•  Facilities management •  Airfield assessment •  Road network analysis (convoys) •  Propagation coverages •  Observation post siting analysis •  Perspective views

CCM Analysis

CCM & Viewshed

Facilities Management

Airfields

Network Analysis

Antenna Propagation Coverage

Trajectories Representation

Observation Post Siting Analysis

Perspective Views